Modeling and analyzing knowledge transmission process considering free-riding behavior of knowledge acquisition: a waterborne disease approach
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Publication:2066375
DOI10.1016/J.PHYSA.2021.125769OpenAlexW3119317015MaRDI QIDQ2066375
Publication date: 14 January 2022
Published in: Physica A (Search for Journal in Brave)
Full work available at URL: https://doi.org/10.1016/j.physa.2021.125769
Related Items (3)
A dynamics model of coupling transmission for multiple different knowledge in multiplex networks ⋮ Global stability and optimal control analysis of a knowledge transmission model in multilayer networks ⋮ ON FRACTAL-FRACTIONAL WATERBORNE DISEASE MODEL: A STUDY ON THEORETICAL AND NUMERICAL ASPECTS OF SOLUTIONS VIA SIMULATIONS
Cites Work
- Unnamed Item
- Global dynamics of a network epidemic model for waterborne diseases spread
- Multiple transmission pathways and disease dynamics in a waterborne pathogen model
- Global dynamics of multi-group SEI animal disease models with indirect transmission
- Network structure and the diffusion of knowledge
- Global-stability problem for coupled systems of differential equations on networks
- Modeling of knowledge transmission by considering the level of forgetfulness in complex networks
- Dynamics of cholera epidemics with impulsive vaccination and disinfection
- Global dynamics of a reaction-diffusion waterborne pathogen model with general incidence rate
- On the intrinsic dynamics of bacteria in waterborne infections
- Cheater-altruist synergy in public goods games
- Knowledge transmission model with consideration of self-learning mechanism in complex networks
- Reproduction numbers and sub-threshold endemic equilibria for compartmental models of disease transmission
- Dynamics of a reaction-diffusion waterborne pathogen model with direct and indirect transmission
- Review mechanism promotes knowledge transmission in complex networks
- Dynamics of a waterborne pathogen model under the influence of environmental pollution
- Knowledge diffusion in complex networks by considering time-varying information channels
- Modeling study of knowledge diffusion in scientific collaboration networks based on differential dynamics: a case study in graphene field
- Global stability of a multipatch disease epidemics model
- Dynamics of a waterborne pathogen model with spatial heterogeneity and general incidence rate
- Global stability of a multiple infected compartments model for waterborne diseases
- Cholera dynamics with bacteriophage infection: a mathematical study
- Statistical mechanics of complex networks
- A graph-theoretic approach to the method of global Lyapunov functions
- The Structure and Function of Complex Networks
- Collective dynamics of ‘small-world’ networks
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